DE3641207A1 - METHOD AND DEVICE FOR STORING LIQUID EXPLOSIVE SUBSTANCES IN THE FORM OF A WATER EMULSION - Google Patents

Description

The invention relates to a method and a device for storing liquid explosives in shape an emulsion in water.

For storing explosives in the form of a water emulsion are different methods and devices known. These have facilities such. B. one mechanical separator through which the explosive for further transport to the processing point is removed from the emulsion. This has to Consequence that pure explosives in these cutting devices is present, the onward transport of which is considerable Danger is connected. The disadvantage is also that the cutting devices are not automatic the different concentrations of the emulsion can adjust, assuming that the decrease in the explosive be constant should.

This avoids the difficulties mentioned be that the explosive water emulsion transported unchanged. But that means not just a relatively large effort for the simultaneous forced transportation is proportionate large amounts of water, but also a relative high effort for separating the water from explosive at the receiving location.

The object of the present invention is, on the one hand the dangers mentioned above, on the other hand also the unnecessarily large transport of water and  associated high effort for divorce on Avoid receiving location.

The object underlying the invention is achieved by the method specified in claim 1 and by the solved device described in claim 6. The Subclaims describe expedient further training the method or the device.

The procedure according to the invention achieves that always an explosive water emulsion for Forwarding is available, which on the one hand has so much water contains that dangers of further transport with Security is avoided, but on the other hand only contains so little water that every effort for excess transportation and later retirement and thus unnecessary water is avoided. By connecting the emulsion part through the bottom gap with the concentration part there is an in dynamic state of the system in which

H · ρ _w ≅ h ₁ · ρ _E

is, where H is the height of the water in the concentration part, h ₁ the height of the emulsion in the emulsion part and ρ _w and ρ _E the density of the water or the emulsion.

According to the intensity of the circulation process in the Emulsion part and possibly still supported due to a slight inclination of the bottom of the emulsion part a more or less occurs towards the bottom gap large part of the emulsion with the higher density  due to the appropriately dimensioned floor gap through into the lower part of the with standing Concentrated part filled with water. Because in this Concentration part does not circulate the liquid takes place, the explosive having the higher density increasingly settling in the water, d. H. the Emulsion is concentrating. This process continues as long held until the concentration of the emulsion in According to the chosen conditions has reached a predetermined or predetermined value.

If the concentration part of the container is not pre-concentrated Explosive water emulsion removed, it flows again due to its higher density back in the emulsion part and is in this again emulsified.

On the other hand, the concentration part is pre-concentrated Removed emulsion, the one described above settles Proceed accordingly.

The dynamics of the system can be further improved in that one or more openings, for example bores, slots or the like, are provided in the partition wall at a height h ₂ below the liquid level.

The height h ₁ of the emulsion is then defined as follows from the static part and the dynamic part of the flow loss through the opening at the height h ₂:

where ϕ represents the concentration factor at the opening (s).

A flow velocity is thus at the opening or openings from

receive.

Since the first root expression is a constant at a given height h ₂, the flow rate increases with increasing specific weight of the emulsion. This means that, with less explosive in the water emulsion, less water flows through the opening or openings in the emulsion part and thus less emulsion gets into the concentration part through the bottom gap. This in turn means that a thinner emulsion in the concentration section has a longer concentration time than a thicker emulsion. By measuring the height h ₂ it is in your hand to influence the steepness of the increase in the flow rate, that is to say to adjust the concentration time and the flow rate in the concentration section in the desired manner and to adapt it to the desired conditions.

A density measurement in the emulsion part, the range of which is defined from 0 to 1, namely 0 for pure water and 1 for pure explosive, allows the density of the emulsion E to be determined using the formula:

ρ _E = ρ _w + Δ Lh ( ρ Expl. - ρ _w )

where ρ Expl. and p _w the density of the pure explosive or the pure water and Δ Lh the height difference between two density sensors in the emulsion part.

The total amount of explosive in the concentration section then results from

M Expl. = Area _E · Δ Lh · h ₁ · ρ Expl.

where the area _{E is} the cross-sectional area of the emulsion part and the other sizes have the meaning already mentioned.

The invention is in the drawing in one embodiment shown and is based on this below explained.

The container 1 is divided by the partition 2 leaving a bottom gap 3 in the emulsion part 4 and the concentration part 5 . The bottom 6 of the emulsion part 4 is formed after the bottom gap 3 to gently sloping at a flat angle.

The line 7 for the introduction of explosive or explosive-water emulsion and the two sensors 8 and 9 of the density measuring device 10 open into the emulsion part 4 . Furthermore, the circulation device 11 , which is designed here as a two-stage stirrer, is arranged in the emulsion part 4 and is driven in a known manner by means of the schematically indicated drive 12 .

The line 13 with the control valve 14 for the introduction of water opens into the concentration part 5 . Furthermore, the level control device 15, 15 a with overflow 16 is provided in the concentration part 5 . As shown by the dash-dotted line, the level control device is functionally connected to the control valve 14 . At the lower end of the concentration part 5 near the bottom 17, the outlet opening or the connecting piece 18 is provided for the removal of concentrated emulsion. Furthermore, the concentration part 5 has the connecting piece 19 .

The partition 2 is provided with one or more openings 20 of circular, slit-shaped or other suitable cross-section.

The operation of the device described is carried out in such a way that the container 1 is first filled with water via the line 13 to a predetermined level. The agitator 11, 12 is then put into operation and the explosive or the explosive-water emulsion is introduced into the emulsion part 4 via the line 7 . In order to avoid hydraulic shocks to the explosive, the speed of the agitator 11, 12 is expediently ramped up slowly, for example over a period of approximately 20 seconds, to the intended target speed and an explosive-water emulsion of a predetermined density is generated in the emulsion part 4 .

Under the influence of the agitator 11, 12 , emulsion subsequently passes from the emulsion part 4 through the bottom gap 3 into the concentration part 5 . Since circulation or stirring is not carried out in this, the emulsion has the opportunity to concentrate in the desired manner while the explosive is being moved.

After the desired concentration has been reached, the emulsion can be drawn off via the removal opening 18 and passed on for further processing.

By connecting the described device via the nozzle 18 and 19 to a device for conveying liquid explosives according to DE-PS 20 55 093 z. B. get a system in which there is only emulsified explosive at all times, and thus the risk is minimized, but preconcentrated explosive is fed to a transport injector in a defined manner, with used water via the level control 15, 15 a and possibly discharged explosive in the form pure explosive or in the form of an explosive-water emulsion is replaced via line 7 , depending on whether batch-wise, discontinuous or continuous operation is planned or carried out.

The relationships shown in the drawing are only to be understood as examples. So it can prove to be expedient or necessary, depending on the type of explosive involved, to realize a more or less high density of the emulsion in the emulsion part 4 , or also a more or less strong concentration in the concentration part 5 , which means for the sizes H , h ₁ and Δ H give correspondingly different values. In accordance with and in accordance with the respectively applicable requirements, the shape and volume of the container 1 and the cross-sectional ratios of the emulsion part 4 to the concentration part 5 can of course also be varied accordingly. Variable is of course also the size Δ Lh, as well as the lower end of the conduit 7 may be positioned differently than shown. The same applies to the arrangement of the connecting piece 19 , in which it is only important that it is carried out so that when connecting the device according to the invention to the device according to DE-PS 20 55 093, the connecting piece 19 remains in an area in which there is always pure water in the concentration section 5 . Accordingly, the connecting piece 19 could, for example, also be provided at a level located above the opening (s) 20 .

Depending on the explosive used in each case and the density of the emulsion in the emulsion part 4 which is deemed appropriate for this and its concentration in the concentration part 5 , it may also prove expedient or necessary to determine the shape and cross-sectional dimensions of the base gap 3 and the opening (s) 20 differently .

For example, the bottom gap can be designed as a slot extending over the entire width of the container 1 or as a larger height corresponding only over a part of the width of the container 1 . It is also conceivable that several slot-shaped openings are provided across the width of the container. In any case, regardless of the volume of the container parts, the height of the slot is always dimensioned so large that a closing of the bottom gap due to the surface tension of the explosive is reliably avoided.

Similar considerations apply mutatis mutandis with regard to the opening (s) 20 , which can be designed both in the form of a single or several slots or, preferably, also as one or more circular bores. It is essential that the total cross-section of the opening or openings 20 and their arrangement in height h ₂ is correctly dimensioned or made according to the respective conditions.

In order to adapt to different conditions, for example when using different explosives, it is advantageous to make the clear cross section of the bottom gap 3 and the opening or openings 20 variable.

Corresponding considerations naturally also arise with regard to the inclination of the bottom 6 of the emulsion part 4 and also with regard to the cross-sectional shape of the container 1 or the cross-sectional shape of the emulsion part 4 and the concentration part 5 . In any case, the conditions are always such that a perfect flow of emulsion from the emulsion part 4 into the concentration part 5 or vice versa always takes place in such a way that undesirable accumulations of explosives which could lead to an undesirably high concentration are reliably avoided.

Claims (12)

1. A method for storing liquid explosives in the form of a water emulsion, characterized in that two container parts connected to one another in the manner of a communicating vessel are filled with water to a predetermined height via a bottom gap, then the water in one of the two container parts (emulsion part ) circulates continuously, then introduces a predetermined amount of explosive or explosive-water emulsion into this part of the container and continues to circulate until a sufficient amount of emulsion has concentrated in the other part of the container (concentration part) to the intended level, and finally under simultaneous supply of a corresponding amount of water in the concentration part and / or explosive or explosive-water emulsion in the emulsion part, the concentrated emulsion is removed from the concentration part near the bottom thereof. 2. The method according to claim 1, characterized in that that the two container parts in the area below the liquid level by a or several additional openings with each other get connected. 3. The method according to claim 2, characterized in that the connection cross section is changeable is trained.   4. The method according to any one of claims 1 to 3, characterized characterized in that the cross section of the Bottom gap is formed changeable. 5. The method according to any one of claims 1 to 4, characterized in that the bottom of one Container part (emulsion part) after the floor gap is too weakly inclined. 6. Device for performing the method according to one of claims 1 to 5, characterized by a by means of a partition ( 2 ) leaving a bottom gap ( 3 ) in two parts connected to each other in the manner of a communicating vessel divided container, one of which part ( Emulsion part; 4 ) provided with a circulating element ( 11, 12 ) and connected to a line ( 7 ) for the supply of explosive-water emulsion or explosive, the other part (concentration part; 5 ) at its bottom ( 17 ) with a Removal opening ( 18 ) and its upper area is connected to a line ( 13 ) for the supply of water. 7. The device according to claim 6, characterized in that the partition ( 2 ) in the upper region, but below the respective liquid level in the container parts ( 4, 5 ) is provided with at least one opening ( 20 ). 8. The device according to claim 6 or 7, characterized in that the cross section of the bottom gap ( 3 ) and / or the opening ( 20 ) is variable. 9. Device according to one of claims 6 to 8, characterized in that the emulsion part ( 4 ) with a measuring device ( 8, 9, 10 ) for the density difference and the concentration part ( 5 ) with a level control device ( 15, 15 a) is provided . 10. The device according to claim 9, characterized in that the level control device ( 15 , 15 a) with the water supply line ( 13 ) is in operative connection. 11. Device according to one of claims 6 to 10, characterized in that the concentration part ( 5 ) is provided with a water overflow ( 16 ). 12. Device according to one of claims 6 to 11, characterized in that the bottom ( 6 ) of a container part (emulsion part; 4 ) is slightly inclined towards the bottom gap ( 3 ).